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How To Take Bacteria Samples

Sampling Air For Bacteria
Bacteria air samples are taken by impacting air onto some suitable growth media. Two of the commonly used samplers are Andersen (N6 Single Stage) and Reuter Centrifugal sampler (RCS). The Andersen sampler uses petri-dishes while the RCS uses agar strips. For environmental bacteria, a general purpose media such as Tryptic (Trypticase) Soy Agar (TSA) can be used.

Sampling Surfaces For Bacteria
Sterile cotton swabs can be used to sample for bacteria contaminating surfaces. The swabs are then sent immediately to a laboratory for culturing and identification of the bacteria to genus or species.

How To Collect Swab Samples For Microbiological Testing

Sterile swabs can be used to test the level of microbial contamination on various surfaces such as air conditioning units, kitchen equipment, hospital wards, spas or any other place. Swab samples can be analysed for total viable counts (usually referred to as colony forming units) or specific indicator organisms for food spoilage or sewage contamination. Swab samples are easy to collect.

How To Collect Swab Samples

  • Wear gloves
  • Select a sampling area of about 10 cm X 10 cm (or 20 cm x 20 cm)
  • Break the seal round the tube containing the swab
  • Remove the swab from the tube and rub and roll it firmly several times across the sampling area.
  • Return the swab into the tube and label the sample
  • Send the sample to the laboratory for analysis.

If one is sampling a dry surface, it is recommended that a wet or moistened swab is used. The swab test method has proved a popular testing method with flood damage insurance claims, where there may be sewage contamination. If swab samples are collected for culture analysis, they should be sent to the laboratory within 24 hours after collection. If the analysis of the swab samples involves enumeration of the microbial contaminants, the size of the area sampled should be provided to the lab.

How To Collect Mold And Bacteria Samples From Air

Collecting mold and bacteria samples from air is very easy. The first thing to decide is the kind of results you want and for what purpose. This will help you to decide on the sampling equipment and the media to use. For example, if sampling for a specific bacterium or fungus, you would want to use a sampling agar media that is suitable for the growth of the target organism. The efficiency of the air sampling pumps for the collection of the target organism has also to be considered.

Sampling equipment can be expensive. However, for a company that does not collect air samples every other week, renting the equipment is a better option. Sampling media can be obtained directly from the manufacturers or their resale agents. For companies collecting only a few samples in a month, sampling media can be obtained from a good mold testing laboratory.

Moulds commonly found in carpet and mattress dust

A number of moulds are frequently found in carpet and mattress dust. Eurotium repens is the most frequently detected mould in mattress dust. Others include Aureobasidium pullulans, Alternaria alternata, Penicillium chrysogenum, Aspergillus penicilloides and Aspergillus restrictus.

More than 100 species of moulds have been recorded from carpet dust. As with mattress dust, the most frequently isolated mould in carpet dust is Eurotium repens. The others are Penicillium chrysogenum, Alternaria alternata, Aureobasidium pullulans and Phoma herbarum.

Concentrations of these moulds in carpet and mattress dust can be as high as 70 million colony forming units per gram of dust. Such high concentrations of moulds are likely to cause respiratory allergy or irritating symptoms. Therefore, it is import to regularly HEPA vacuum the carpets, mattresses and upholstered furniture to reduce the dust and spore concentration. If people are suffering from reoccurring respiratory allergy or irritating symptoms in a building where there is no visible mould, it is suggested that dust be tested for the types and concentrations of mould present.

Legionella: Health Effects, Occurrence and Sampling

Health effects of Legionella

In 1976, in Philadelphia, USA, over 200 attendees of the US-American Legion, developed pneumonia. The disease was later called “Legionnaires’ disease”. The causative agent, a Gram-negative bacterium, was named Legionella pneumophila. Legionella pneumophila causes 85-90% of all cases of Legionella infections (legionellosis). There are over 40 species of Legionella.

Legionella pneumophila can cause very severe infection of the respiratory system. However, Legionnaires’ disease epidemics are rare but the disease is fatal if untreated. The disease may develop within 2 to 13 days (average 5-6 days).

Another form of legionellosis is Pontiac fever, named after an outbreak in 1968 in Pontiac, USA. This form of disease, caused by a number of Legionella species, is milder than Legionnaires’ disease. Pontiac fever develops within 48 to 72 hours and the illness may clear in 2-5 days. No fatal cases have been reported in relation to Pontiac fever. This disease mainly appears as epidemics. Pontiac fever is believed to be a reaction to inhaled Legionella antigens rather than an infection.

Disease transmission

There is no evidence for transmission of legionellosis from person to person or by ingestion. Legionella infection occurs when people inhale the bacterium via fine water droplets as aerosols from the environment. Indoor transmission of legionellosis has been reported via contaminated hot water supplies in hospitals, hotels and other public buildings, respiratory therapy equipment, jacuzzis, spas and air-humidifiers.

Occurrence

Legionella bacteria are part of the natural aquatic bacterial population of lakes and rivers. They are present in all types of fresh water, including tap water. Legionella multiply in water, using other microorganisms like bacteria, algae and protozoa. Their concentration in fresh water is influenced mainly by the temperature. They are isolated more frequently and in higher concentrations from warm water (30 to 50 °C.). However, Legionella also survive at much lower temperatures indoors as well as outdoors. At temperatures above 60 °C Legionella can’t survive.

Sampling Of Legionella

Sampling of Legionella in indoor air or water on a routine basis is not recommended. However, sampling is recommended to:

  • determine the source of outbreaks of legionellosis
  • check the effectiveness of maintenance practices and control measures for hot water supplies and humidified ventilation systems
  • guarantee the safe use of hot water supplies and humidified ventilation systems.

When investigating the water services within a building for Legionella, the condition of pipes, the joining methods used, the presence of lagging, sources of heat, and the standard of protection afforded tanks should be noted, as well as disconnected fittings, ‘dead-ends’, and cross-connections with other services.Water Sampling
Water samples should be collected in sterile autoclavable plastic containers. The samples should be taken from:

  • the incoming supply;
  • tanks;
  • an outlet close to, but downstream of, each tank;
  • the distant point of each service;
  • the water entering and leaving any fitting under particular suspicion.

Surface Sampling
Using swabs, surface samples should be taken from shower heads, pipes and taps. Also, sludge, slime or sediments within building water services or humidifiers can also be collected, particularly where accumulation occurs.

Sample Handling and Storage
Samples should be stored at room temperature (20 ± 5 °C.) in the dark and should be processed within 2 days. That means the samples should be sent to the laboratory within 24 hours. It is also important to confirm with the lab that they have the necessary media before sampling is done.

Air sampling
The presence of Legionella in indoor air can be investigated using Reuter Centrifugal Sampler (RCS) or the Andersen sampler. Regardless of the sampler used, the recommended sampling agar at present is BCYE-agar.

References

  1. Flannigan, B., R.A. Samson, and J.D. Miller (Editors). Microorganisms in home and indoor work environments: diversity, health impacts, investigation and control. 2001. London, UK: Taylor & Francis (ISBN: 0-415-26800-1).
  2. Wanner, H-U, AP Verhoeff, A Colombi, B Flannigan, S Gravesen, A Mouilleseux, A Nevalainen, J Papadakis, and K Seidel. 1993. Biological Particles in Indoor Environments. Indoor Air Quality and Its Impact On Man. Brussels: Commission of the European Communities. Report No. 12.

For more information on indoor bacteria, please visit http://www.moldbacteria.com/ or call 905-290-101.

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